Impact of Climate Change on weeds, pest, diseases and others … · Impact of Climate Change on...
Transcript of Impact of Climate Change on weeds, pest, diseases and others … · Impact of Climate Change on...
Impact of Climate Change on
weeds, pest, diseases and others
and Crop Improvement
Vellingiri Geethalakshmi
Tamil Nadu Agricultural University
Outline
• Introduction
• Impact of climate Change on weeds
• Impacts of Climate Change on Pests
• Impacts of Climate Change on Diseases
• Adapting to Climate Change
• Crop Improvement
• Conclusions & Future directions
Introduction
• climate change affects Agriculture
• Agro-ecosystem : crops / pests /
Natural enemies / others
• Diseases and insect pests damage :
~42% loss in 8 important food and
cash crops ~300 billion $
• Climate change influences the
ecology of weeds, pests and
disease, with possible implications
for crop protection and pesticide
use.
WEEDS• Short life cycles - High reproductive rates -
Rapid response to rainfall events - Adapted to a wide range of environments & soil –“struggle for existence”
• Compete with crops for nutrients, water, light
• Impact: Reduces yield & quality/inhibit harvest.
• Health problem (poisonous plants, allergens)
Climate change affect weeds as much as crops
• Higher CO2 : stimulate photosynthesis and growth, reduce ET and increase WUE
• Competitive : greater genetic variation / physiological plasticity / may gain more advantages from climate change than crops
• Possess many pre-adaptations at the molecular, biochemical or whole plant level to respond more positively to CC
Impacts of Higher Temperature
• Offset benefits of elevated CO2 (Bunce& Ziska 2000).
• Allow sleeper weeds to become invasive
• Expansion of weeds into higher latitudes or higher altitudes
• Very aggressive weeds that are currently found in the lower latitudes are limited in the higher latitudes
• Itchgrass, a profusely tillering, robust grass weed could invade the central Midwest and California with a 3°warming trend (Patterson, 1995).
• Response to drought in agronomic
conditions is dependent on
species and cultural conditions.
• Any factor which increases
environmental stress on crops may
make them more vulnerable to
attack by insects and plant
pathogens and less competitive
with weeds (Patterson, 1995).
Impacts of Precipitation
C4 weeds in C3 crops
• 14 of the world’s worst weeds are C4 plants
• 76% of the harvested crop area is with C3 crops
• Hypothesis: C3 crops would benefit more from elevated CO2 than C4 weeds, losses due to C4 weeds might decrease. Patterson & Flints (1980), Coleman & Bazzaz (1992) and Ziska (2003).
• Research gap : Temperature increase /drought in combination with elevated CO2 trends are not clear (Fuhrer 2003, Bunce & Ziska 2000).
• Optimal temperatures for growth in C4 plants are generally higher than optimal temperatures for C3 plants (Flint & Patterson 1983), but with higher CO2 the optimum temperature of many C3 plants also increases (Bunce & Ziska 2000).
• In drought situations C4 weeds might also have advantages over C3 crops under elevated CO2 (Ward et al. 1999).
C3 weeds in C4 crops
Elevated CO2 under sufficient water condition will lead to higher C3 weed competitiveness in C4 crops.
At elevated CO2, seed yield or total above ground biomass of sorghum was significantly reduced by C3 weeds (Ziska 2003).
C3 weed dandelion (Taraxacum officinale) produced more fertile seeds and larger seedlings under elevated CO2 (McPeek & Wang, 2007).
C4 crops might out-compete better growing C3 weed in drought situations (Tang et al. 2009).
C3 weeds in C3 crops & C4 weeds in C4 crops
• Logic : Same type of plants in the same ecosystem would react to changes in environment a similar way. But, the magnitude differs.
• Biomass accumulation from CO2 doubling in crops: +31% in wheat, +30% in barley, +27% in rice, +39% in soybean, +57% in alfalfa, and +84% in cotton.
• Biomass accumulation from CO2 doubling in C3 weeds: 79% to 272% compared to ambient CO2 (Patterson 1995).
Invasive Weeds
• Introduction: Warming polar regions will see increased traffic and new invasives.
• Colonization: More frequent or severe storms provides opportunities for establishment of new invasives.
• Distribution: Many invasives are range-limited by cold temperatures.
• Management: Chemical control of invasive plants can be altered with rising CO2 / climate
Potential impacts of climate change on weeds significant to
agriculture in southern AustraliaWeed Impact
Blackberry Expected to retreat southwards and to higher altitudes because it is
sensitive to higher temperatures and drought
Chilean needle
grass
Expected to increase its range because it is highly invasive (long
lived, seed dispersed by wind and water) and drought tolerant
Gorse Expected to retreat southwards because it is drought sensitive.
Lantana Expected to continue its move southwards into high-rainfall zones
of northern New South Wales
Mesquite Some risk that it may move into lower-rainfall areas because it is
very drought tolerant.
Parthenium Not suited to winter-dominant rainfall areas. May move into
summer-dominant, higher-rainfall (>500 mm) regions.
Serrated
tussock
Expected to retreat southwards and to higher altitudes because it is
sensitive to higher temperatures.
As a drought-tolerant plant, it should become more invasive in areas
where temperature allows.
Prickly acacia Expected to move southwards and into arid areas.
CSIRO and the Bureau of Meteorology 2007, Climate Change in Australia, a report,
CSIRO, Canberra. http://www.climatechangeinaustralia.com.au
Weed control• The Differential effects of CO2 and CC will alter
the weed-crop competitive interactions
• Changes in temp, precip, wind and humidity may
affect the effectiveness of herbicides
• Climate models can predict the likely impacts on
the future distribution of weeds (management)
• Greater increase in biomass will result in dilution
of herbicide applied, making weed control more
difficult and costly (Patterson, 1995)
• Due to change in anatomical, morphological and
physiological changes - increase leaf thickness,
reduce stomatal number and conductance that
possibly limited uptake of foliar applied
herbicide
CLIMATE CHANGE
AND PESTS
Globally 360,000 insects
species, mainly live from
plant material.
Damage by chewing on
plant tissues / sucking the
plant sap / transmit
viruses.
Drivers
• higher temperature may be more favourable for
the proliferation of insect pests (longer growing
seasons, higher possibility to survive during winter
time)
• Enhanced CO2 may affect insect pests through
amount and quality of the host biomass (higher
consumption rate of insect herbivores due to
reduced leaf N)
• Altered wind patterns may change the spread of
both wind-borne pests and of bacteria and fungi
• Increased frequency of floods may increase
outbreaks of epizootic diseases (i.e. African Horse
Sickness)
CC and insect pest on crops
• Herbivory : – Global warming will increase insect herbivory (Price, 2002).
– In contrast, Fajer (1989) argues that an enriched CO2, leading to low plant quality, will reduce herbivore densities and increase the probability of extinction.
• Insects are ectothermic, very sensitive to temperature, and cannot sustain living below and above certain thresholds.
• Global warming might benefit many insect species in the temperate regions – Changes in geographical distribution
– Increased overwintering
– Changes in population growth rates
– Increases in the number of generations
– Extension of the development season
– Changes in crop-pest synchrony
– Changes in inter-specific interactions and increased risk of invasion by migrant pests
CC and insect pest on crops
• Many tropical insect species may become extinct as they are already living at environmental temperatures close to their optimum
• Reduced nutrient quality of C3 plants might lead to a compensation by increased feeding of many insects (Lincoln et al. 1986, Whittaker 1999, Emmerson et al. 2004, DeLucia 2008, Barbehenn et al. 2004).
• Population densities of chewing insects would be unaffected or decrease, but do not increase while sap sucker population densities might increase under increased CO2 concentrations (Whittaker, 1999)
Predicted impact of global warming
by 2100 on insect species
Deutsch et al. (2008).
Positive impacts (positive
values) are displayed
yellow to red, while
negative impacts
(negative values) are
shown in blue
• Severe droughts
resulting in a reduction
of soil water will
negatively affect soil
nematodes.
• Higher average
temperatures will
probably have little
effect, since thermal
conductivity of soils is
low (Larcher 2001).
Nematodes
Expected responses of Heteroptera species and communities
under two scenarios of further climate change
Increased CO2 effects depend on insect-plant interaction
• Increased carbon : nitrogen ratio in plants makes for poorer forage for insects
• Shift in plant defenses : Fewer toxins, tougher leaves, more tannins/ phenols
• Deficiencies in micronutrients
• Help for insects:– Nitrogen addition can make for better forage
– Shift in plant defenses from nitrogen to carbon based
– Consume more plant to make up for less nitrogen
R. Srygley ,USDA
Non-crop pests could have an impact on arable rotations
• Elevated CO2 - increased N fixation in legumes
• Numerous and bigger root nodules = more N fixed
(Soussana & Hartwig, 1996; Zanetti et al., 1996;
Hungate et al., 1999)
• Elevated CO2 - results in more weevils
• more root nodules - a surge in root pests
• Sitona spp. weevils – new born stages
specifically target root nodules
Interactions among components of the disease triangle
and potential outcomes
Changes in
host,
pathogen
and climate
can increase
or decrease
the amount
of disease as
a result of
their
interactions
Garrett et.al. (2009)
CC influence on Plant Diseases• Increased frequency of heat and drought
– may contribute to disease susceptibility/resistance.– Drought can aggravate the effects of soil borne
diseases, like Macophomina, Fusaria and others
• Temp governs the rate of reproduction formany pathogens
• Elevated CO2 levels– change plant structure- increased leaf thickness,
higher leaf area, higher plant biomass- all thesewould influence infection by pathogens
– CO2 increases pathogen load on C3/C4plants/grasses
• Elevated O3 can change the leaf surfacestructure- affecting physical topography andchemical composition, structure of epicuticularwax- may influence pathogen infection- likelyenhanced infection by necrotrophic pathogensand root-rot fungi
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Effects on Plant Pest & disease
management
• Delayed/adjusting planting dates less effective
• Increased vulnerability to biocontrol agents
• Reduced efficacy of chemical control
• Risk of movement of invasive pathogenspecies
• Reduced effectiveness of durable resistance
• uncertainty for management methoddecision making
• Changing disease management strategy
Crop Improvement
• To overcome the pessimistic influence of
abiotic stresses
• New, improved and tolerant crop varieties
• Contemporary breeding techniques
• Through understanding of the mechanisms
that counteract detrimental climate changes
Increasing the Yield Potential of Rice : Various strategies
(1) conventional hybridization and selection procedures, (2) Ideotype breeding, (3) Heterosis breeding, (4) Wide hybridization, (5) Genetic engineering
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Conclusions..
• CC affects the pest / disease by increasing/decreasing the encounter rates between host and pathogens by changing the ranges of the two species
• Disease severity-positively correlated with increased virulence of pathogens which are mediated by host resistance that is affected by climate change
• CC will affect plant pest and diseases in relation to other global change phenomena- new species, new vectors, shifts in land use, expansion of tropical/temperate areas, loss of biodiversity etc.
Adapting to Climate Change• For growers
– Early warning systems for managing pests within-season by
tactical decision making
– Constructing longer-term (season) decision support system
• For plant breeders and pesticide developers
– Prioritization of diseases/weeds/pests
– Identification of vulnerable regions / hotspots
• For policy makers / donors
– Identification of important problems for future investment
– Application of financial tools as buffer for protecting the farmers
from increased variability
• In natural systems
– Distribution of resistance genes
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Future directions
Increased focus needed on:• How a changing environment affects host-pathogen
evolution
- pathogen characteristics, such as frequency of generation and proportion of sexual reproduction affect the rate of adaptation
- host characteristics, such as life span affects rates of adaptation
of both host and pathogen populations
• Are invasive plant species better able to adapt to CC and move to new areas rapidly?
• Local, regional and international cooperation and collaboration needed to understand the problem and find solutions